Polyolefins Vitrimers: Design Principles and Applications

Ahmadi, Mostafa; Hanifpour, Ahad; Ghiassinejad, Sina; Ruymbeke, Evelyne Van

doi:10.1021/acs.chemmater.2c02853

Cited by 62 publications

(48 citation statements)

References 138 publications

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“…Recently, however, the possibility of tuning CANs through physical means has been proposed, 161–163 making use of phase separation and aggregation, which will be discussed in the next paragraphs. By inducing phase separation in CANs, the aim is mostly to enhance mechanical and physical properties ( e.g.…”

Section: Covalent Adaptable Network (Cans)mentioning

confidence: 99%

“…[154][155][156] In addition, network characteristics have also been considered, such as the crosslinking density, 157,158 or building in (a small degree of) permanent non-dynamic crosslinks. 159,160 Recently, however, the possibility of tuning CANs through physical means has been proposed, [161][162][163] making use of phase separation and aggregation, which will be discussed in the next paragraphs. By inducing phase separation in CANs, the aim is mostly to enhance mechanical and physical properties (e.g., to increase the T g or reduce creep), add new functionalities, and/ or change the overall morphology of the material through dividing the material in different domains.…”

Section: Chemistry Of Cansmentioning

confidence: 99%

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Phase separation in supramolecular and covalent adaptable networks

et al. 2023

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Section: Covalent Adaptable Network (Cans)mentioning

confidence: 99%

Section: Chemistry Of Cansmentioning

confidence: 99%

Phase separation in supramolecular and covalent adaptable networks

et al. 2023

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“…Despite the diversity of transient bonds, which spans from reversible covalent to noncovalent interactions, including but not limited to hydrogen bonds, host–guest interaction, and metal–ligand coordination, only a few of them can react in a heterocomplementary fashion, which is necessary to avoid the formation of primary loops. This includes the majority of reversible covalent bonds, whose stability can be adjusted using external catalysts or stimuli. , A prime example is the hydrazone bond formed between aldehyde and hydrazine groups, whose dissociation rate can be tuned over two orders of magnitude using aniline as the catalyst . In the same way, the dissociation of boronic ester bonds formed between boronic acid and diols strongly depends on and can be tuned by pH and temperature. − Alternately, leveraging the combination of hydrophobic and electrostatic interactions, polymer precursors functionalized with heterocomplementary macrocycles and various guests are reported to form transient hydrogels with a stability that is tunable in more than five orders of magnitude. , Similarly, heterocomplementary hydrogen bonding groups are used to suppress the macroscopic phase separation between immiscible polymer precursors, but their utility in hydrogel formation is normally limited due to the competition with water. , In contrast, Sakai and co-workers have recently formed transient hydrogels using tetraPEG precursors grafted with DNA sequences, which form heterocomplementary duplexes mediated through hydrogen bonds .…”

Section: Introductionmentioning

confidence: 99%

Connectivity Defects in Metallo-Supramolecular Polymer Networks at Different Self-Sorting Regimes

et al. 2023

Self Cite

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The properties of polymer networks depend on their connectivity, specifically on the presence of connectivity defects like loops and dangling ends. While chemically crosslinked networks have a frozen distribution of defects on multiple length scales, equivalent transient ones are capable of self-repairing. To study this potential, we employ spatial hindrance as an effective self-sorting mechanism to develop metallo-supramolecular polymer networks based on heteroleptic complexes. We functionalize tetra-arm poly(ethylene glycol) (tetraPEG) chains with the mesitylene-substituted phenanthroline ligand, which is incapable of homoleptic complexation, yet it can form heteroleptic complexes with tetraPEG precursors functionalized with unsubstituted phenanthroline or terpyridine ligands. This way, the formation of primary loops can be avoided upon selective formation of heteroleptic complexes. Nevertheless, the coordination geometry preference of the utilized metal ion can tune the extent of self-sorting and consequently the network structure and defect composition. The latter is pursued via MQ-NMR, and periodic density functional theory simulations are used to visualize the structure and explain its relationship with the dynamics as measured by rheology. Our results demonstrate that Cu(I) can inherently adopt the geometry requirements of both desired heteroleptic complexes by benefiting from the πstabilization effect, thereby creating a network with the least primary loops and dangling ends.

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“…Bio-based thermosets that consist of biogenic carbons can be a solution because their use can reduce fossil fuel consumption and the carbon footprint . In particular, with the help of dynamic covalent chemistry, they are reprocessable and chemically recyclable; thus, they constitute bio-based covalent adaptable networks. , A variety of biomasses have been exploited for this purpose: vegetable oils − (including vanillin, − eugenol, , and cardanol , ), natural acids, − flavonoids, , and biopolymers, for example, polysaccharides, natural resins, and lignins. − Most of them contain β-hydroxy ester bonds that are commonly derived from epoxide, promoting transesterification due to the presence of free hydroxyl groups adjacent to the esters . Moreover, dynamic covalent bonds such as imine, disulfide, hindered urea, , acetal, boronic ester, and carbamate have been applied to build renewable dynamic networks.…”

Section: Introductionmentioning

confidence: 99%

“…24−30 Most of them contain β-hydroxy ester bonds that are commonly derived from epoxide, promoting transesterification due to the presence of free hydroxyl groups adjacent to the esters. 31 Moreover, dynamic covalent bonds such as imine, 32 disulfide, 16 hindered urea, 6,10 acetal, 27 boronic ester, 11 and carbamate 33 have been applied to build renewable dynamic networks.…”

Section: ■ Introductionmentioning

confidence: 99%

Synthesis of Renewable, Recyclable, Degradable Thermosets Endowed with Highly Branched Polymeric Structures and Reinforced with Carbon Fibers

Choi

Jeong

et al. 2023

Macromolecules

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This paper demonstrates the molecular design of renewable polymer thermosets that are chemically recyclable yet degradable on demand. In this design, the thermosets comprise a limonene-based highly branched polymer, which has been synthesized via the regioselective thiol−ene reaction between natural limonene and multifunctional thiol, and a Meldrum's acid derivative for the click/declick reaction of thiol groups that are deliberately positioned on the outer surface of the branched polymer. Thus, the accessible thiols expedite the covalent bond exchange reaction and enable the formation of a network and bulk recycling of the entire network; the labile cross-linkers enable molecular degradation or repurposing of the materials under benign conditions. The thermosets can be also reinforced with the addition of carbon fibers. Thus, reversible deformation or self-lamination of the resultant carbon composites, which are degradable and recyclable, was achieved owing to the thermosets, which act as a matrix or binder. We envision that the renewable materials presented here would be advanced by introducing diverse biomolecules or reversible chemistry to develop disposable bio-based platforms that can be further upcycled at the end of their lifecycles.

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Polyolefins Vitrimers: Design Principles and Applications

Cited by 62 publications

References 138 publications

Phase separation in supramolecular and covalent adaptable networks

Phase separation in supramolecular and covalent adaptable networks

Connectivity Defects in Metallo-Supramolecular Polymer Networks at Different Self-Sorting Regimes

Synthesis of Renewable, Recyclable, Degradable Thermosets Endowed with Highly Branched Polymeric Structures and Reinforced with Carbon Fibers

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